JP3119929U - Health band - Google Patents

Abstract

A health band has a negative ion generation layer and a germanium-containing layer, and when wound around and fixed to a predetermined part of the body, promotes blood circulation and quickly removes fatigue of the feet and arms, neuralgia, low back pain, etc. Provide a healthy band that can
A negative ion generation layer 12 in which a fine powder of a negative ion or far-infrared generating substance is mixed with a resin binder on the lower surface of a flexible soft resin band main body 2 and a high-purity inorganic material. It is formed by mixing a germanium-containing layer 10 in which a fine powder of germanium is mixed with a resin binder and applied.
[Selection] Figure 2

Description

  The present invention relates to a health band having a negative ion generation layer and a germanium-containing layer, and when wound around a predetermined part of the body, can promote blood circulation and quickly remove fatigue of the feet and arms, neuralgia, low back pain, etc. Regarding health bands.

  In modern society, people are busy with work, housework, study, etc., and daily fatigue accumulates, and many people complain of stiff shoulders, lower back pain, muscle fatigue, etc. on a daily basis. A number of anti-inflammatory analgesic plasters are commercially available to relieve this fatigue and pain. This anti-inflammatory analgesic plaster often contains a skin irritant component as an anti-inflammatory analgesic, and l-menthol and dl-camphor have local irritating effects, and eczema, rash, etc. may occur, and methyl salicylate is Due to the property of being easily absorbed from the skin, it is easy to get rash if it is applied for a long time at the same location.

  In this anti-inflammatory analgesic plaster, an adhesive substance containing an anti-inflammatory analgesic is spread over the entire cloth surface as a support. If this anti-inflammatory analgesic plaster is applied over a wide range other than the affected area, and if the application lasts for a long time, it is not limited to people who are easily irritated, and even normal people will have itching or redness. In order to reduce this, for example, in Japanese Patent Laid-Open No. 2000-169366, in the sheet-like plaster, the thickened portion is raised only at the substantially central portion of the spread external preparation. JP-A-11-263724, in a thermal plaster, holds a drug-holding piece containing a pepper tincture or the like that imparts a thermal feeling corresponding to the application part inside the periphery of the support on which the adhesive layer is formed, The planar shape of the medicine holding piece is defined as a rectangle.

In an analgesic plaster, when a drug is thickened in the center of a sheet material or a rectangular drug holding piece is held inside a support with an adhesive layer formed around it, rash and redness caused by these drugs can be reduced. Even if it is possible, it cannot be completely avoided, and the duration of the therapeutic effect is not sufficient. On the other hand, the use of sheet-like germanium instead of these drugs is disclosed in Japanese Patent Application Laid-Open No. 58-1465 or Japanese Patent No. 2572520. Germanium ions are generated from the germanium semiconductor, relieving muscle tension by coordinating bioelectric currents, releasing blood congestion and improving blood circulation.
JP 2000-169366 A JP-A-11-263724 JP 58-1465 A Japanese Patent No. 2572520

  The skin contact piece disclosed in Japanese Patent Application Laid-Open No. 58-1465 is formed into a sheet by mixing germanium particles and metal particles, and is a hard plate, so it can be fixed to the body with a bandage or bandage. Unable to avoid discomfort and poor contact with the skin surface. The semiconductor therapeutic agent disclosed in Japanese Patent No. 2572520 specifies a germanium semiconductor thin film or powder as an example of a p-type semiconductor, and forms the p-type semiconductor thin film on the surface of a molded body such as plastic. When the semiconductor therapeutic agent is used to form a thin film on the surface of a hard molded body, it is difficult to avoid an uncomfortable feeling during use if it is fixed to the body with a bandage or the like as described above. When germanium powder is used by kneading with a commercial lotion, since aluminum or the like is added, the purity is lowered, and the problem is that the desired effect does not last for a long time because it easily dissipates from the body.

  On the other hand, bracelets, necklaces or rings exist as products containing germanium having a relatively high purity. Germanium bracelets are advantageous compared to magnet bracelets, etc., because they maintain their effects over a long period of time, but bracelets and necklaces have little contact with the body's skin when used, and fully enjoy the beneficial effects of germanium. Can not. The ring made of germanium has limited contact location and area even if the contact with the skin of the body is perfect, and can enjoy the effect only locally.

  The present invention has been proposed in order to improve the above-mentioned problems related to plasters containing germanium, and provides a health band that can be easily attached and detached by wrapping around a predetermined part of the body instead of the plasters. The purpose is that. Another object of the present invention is to provide a health band to which a negative ion or a far-infrared ray generating substance having a good therapeutic effect is added in addition to high-purity germanium.

  The health band according to the present invention includes a negative ion generation layer in which a fine powder of a negative ion or far-infrared generating substance is mixed with a resin binder on the lower surface of a flexible soft resin band main body, and a high purity The inorganic germanium fine powder is mixed with a resin binder and a germanium-containing layer applied and mixed is formed. When this health band is wound around and fixed to the wrist, ankle, waist, head, etc. of the wearer, the negative ion generation layer and the germanium-containing layer directly contact the skin and act on the wearer.

  The health band of the present invention may be constituted by combining two soft resin sheets with a reinforcing cloth interposed in the band body. In the health band, metal fine powders such as aluminum and silver are added to the resin on the front side sheet, and fine powders of negative ions or far-infrared generating substances are mixed with a resin binder on the lower side surface of the back side sheet. The negative ion generation layer coated and the germanium-containing layer coated by mixing a high-purity inorganic germanium fine powder with a resin binder are mixed.

  In addition, the health band of the present invention may be configured by combining two urethane resin sheets with a reinforcing cloth interposed in the band body. This health band has one of the surface fasteners sewn to the front end of the band body and the other of the surface fasteners sewn to the rear end, and negative ions or far infrared rays are generated on the lower surface of the band body. A negative ion generation layer obtained by mixing and applying a fine powder of a substance with a polyurethane resin and a germanium-containing layer obtained by mixing and applying a high-purity inorganic germanium fine powder with a polyurethane resin are mixed.

  In the health band of the present invention, it is preferable to hold a predetermined amount of the negative ion generation layer and the germanium-containing layer by embossing fine textures on the lower surface of the back sheet. In addition, as a health band for jogging and marathon, when sewing a hemcloth around the band body, it is preferable to sew the front and back of the band body at the same time before and after the insertion piece, The health care table can be fixed by passing it through both plugs.

  The present invention will be described with reference to the drawings. The health band 1 is composed of an elongated band body 2, and the band body is composed of one sheet or a combination of sheets 3 and 5. In the band body 2, a heat insulating sheet or the like can be interposed between the sheets 3 and 5. The length and width of the band main body 2 vary depending on the ankle 21 (FIG. 4), wrist (FIG. 7), neck, head, chest, etc., which are the winding points, and also differ for women, men, and children. When the health band 1 is wrapped around the head or chest, two ankle bands may be connected and used. Moreover, in order to give versatility to the health band 1, you may interpose an elastic sheet in a part of band main body.

  The band body 2 is made of a flexible soft resin, and is composed of, for example, two soft resin sheets 3 and 5 with a reinforcing cloth 7 interposed therebetween, and preferably a urethane resin sheet 2 having a reinforcing cloth 7 interposed therebetween. Consists of a stack of sheets. It is preferable that the band body 2 is made of a soft resin because it easily fits the wearer's skin when wound, and does not dissipate heat from far-infrared radiation to the outside. Further, when the reinforcing cloth 7 is interposed between the sheets 3 and 5, it is possible to prevent the band 1 from being damaged due to repeated pulling during winding.

  As illustrated in FIG. 3, the front sheet 3 is laminated with an upper resin layer 6 on which an appropriate surface pattern 9 made of a trademark, a figure, or the like is printed, a reinforcing cloth 7 disposed in the middle, and the reinforcing cloth. A three-layer structure with the lower resin layer 8 is desirable. The upper resin layer 6 of the front side sheet 3 is added with fine metal powder such as aluminum or silver in a resin such as urethane resin so that far infrared rays and negative ions generated from the back side sheet 5 can be reflected. In the upper resin layer 6, instead of adding the metal fine powder, a metal foil or a metal film is sandwiched between two resin layers, one of which is a thin protective layer, or aluminum, silver, or the like is formed on one resin surface. The metal may be vapor-deposited. If the band body 2 is a single sheet, the front side portion thereof is substantially the same as the upper resin layer 6 of the front side sheet 3.

  On the other hand, like the front sheet 3, the back sheet 5 desirably has a three-layer structure of an upper resin layer 6, a reinforcing cloth 7 disposed in the middle, and a lower resin layer 8 laminated with the reinforcing cloth. If the band body 2 is a single sheet, the back side portion thereof is substantially the same as the lower resin layer 8 of the back side sheet 5. The lower resin layer 8 of the back sheet 5 is embossed with fine embossing by calender embossing, and the application amount of the negative ion generation layer 10 and the germanium-containing layer 12 can be kept on the surface by this embossing. Easy.

  On the lower resin layer 8 of the back sheet 5, a fine uneven pattern such as wrinkles is formed in order to enhance touch, and a thin cloth is pasted after the formation of the negative ion generation layer 10 and the germanium-containing layer 12. May be. In addition, it is possible to partially perform a flocking process or to impart antibacterial properties to the lower resin layer 8 by a photocatalyst.

  The lower resin layer 8 of the back sheet 5 is formed by mixing at least a negative ion generation layer 10 and a germanium-containing layer 12. The layers 10 and 12 may be partially polymerized by coating and forming one layer on the entire sheet surface, or may be partially coated so as not to polymerize both layers. As a result, as illustrated in FIG. 2 or FIG. 6, the negative ion generation layer 10 and the germanium-containing layer 12 are both exposed on the lower resin layer 8, and the negative ion generation layer 10 and the germanium-containing layer 12 Are in direct contact with the skin of the wearer 20 at the same time.

  It is desirable that the total surface areas of the negative ion generation layer 10 and the germanium-containing layer 12 are substantially matched on the surface of the lower resin layer 8. When the layers 10 and 12 are formed by partial polymerization, the latter pattern may be a character, a symbol, a complicated geometric pattern, a concrete pattern, or a combination thereof, while not forming the partial polymerization. In such a case, it is desirable to have a simple planar shape made of a circle or a square such as a lattice pattern, a mesh shape, or a polka dot pattern.

  The negative ion generation layer 10 is applied by adding a fine powder of far infrared radiation material to a resin binder. When the ceramic powder is added to the negative ion generation layer 10, it is necessary that the ceramic powder emits far infrared rays having a wavelength of 4 to 20 μm in a high temperature range. The negative ion generation layer 10 is applied on the back sheet 5 by a silk screen method or a roll coater method, and the thickness may be 5 to 30 μm. The resin binder may be any of a resin latex, a resin emulsion, a resin suspension, a hydrophilic copolymer, a chemically reactive water-soluble resin and the like as long as the fine powder of the radioactive material can be uniformly kneaded.

As this type of ceramic, for example, alumina (Al ₂ O ₃ ), magnesia (MgO), zirconia (ZrO ₂ ), titania (TiO ₂ ), lanthanum, silicon dioxide (SiO ₂ ), Chromium oxide (Cr ₂ O ₃ ), ferrite (FeO ₂ · Fe ₃ O ₄ ), spinel (MgO · Al ₂ O ₃ ), ceria (CeO ₂ ), beryllia (BeO) and the like can be used. Furthermore, EM ceramic (trade name: EM-X, manufactured by Amron) having antioxidative power can also be used.

  With regard to the negative ion generation layer 10, if the health band 1 is kept worn for a certain period of time, the far infrared rays hit the skin of the wearer 20, the temperature rises due to the radiation of the far infrared rays, and sweating is promoted by the thermal effect to generate negative ions. appear. In general, the radiation characteristics of ceramics vary greatly depending on the particle size, particle shape, surface state, filling amount, filling resin, distribution structure, etc., even with the same powder material, so advanced material evaluation techniques are indispensable. For example, alumina-silica-based ceramics and oxide-based ceramics have high selective radioactivity even when dispersed in a resin binder, and non-oxide-based ceramic powders have high overall radiation.

  As far-infrared radiation materials that can be added to the negative ion generation layer 10, natural minerals include tourmaline, serpentine (a magnesium hydrated silicate mineral), sericite, jade, zeolite, sericite, crystal, oolite, mica. Examples include stones. These are pulverized to form a fine powder and added alone or in combination of two or more with ceramics.

On the other hand, with respect to the germanium-containing layer 12, germanium is an element having an atomic number of 32 and an atomic weight of 72.59 that does not change in the air, and has a metal-like appearance but is not a metal but an intrinsic semiconductor. It is described as germanium. Germanium is extracted as tetrachloride GeCl ₄ from ore such as germane or renie ore, purified by distillation and then hydrolyzed, and the generated dioxide GeO ₂ is reduced with hydrogen. When this is refined by the zone melting method, a high purity simple substance having a gray structure and a diamond structure is obtained. Germanium has a melting point of 937.4 ° C., a boiling point of 2830 ° C., a density of 5.32 g / cm ³ (25 ° C.), an electron mobility of 3900 cm ² / V · s, a hole mobility of 1900 cm ² / V · s, and a magnetic susceptibility of −0. .106 × 10 ⁻⁶ cm ³ / g, thermal conductivity 59.9 W / m · K, and becomes a dioxide GeO ₂ at a high temperature.

  Semiconductors such as inorganic germanium include a p-type semiconductor and an n-type semiconductor, and germanium is an electron-deficient p-type semiconductor. When a p-type semiconductor is brought into contact with human skin, blood flow increases due to measurement using a thermography or laser speckle blood flow meter, and the pain-causing substances and fatigue substances remaining in the capillaries are removed.・ Can eliminate shoulder stiffness, neuralgia and muscle pain. In general, for p-type semiconductors, a therapeutic effect is observed in about 80% of the whole specimen. As the purity of inorganic germanium is higher as a semiconductor therapeutic agent, a remarkable therapeutic effect is recognized with respect to muscle pain and the like. Preferably, the purity is 99% or more, and more preferably 99.999% or more, so that it hurts upon contact. There are no side effects.

  Inorganic germanium is used, for example, in the form of a fine powder of 5 μm or less, and this fine powder is uniformly and sufficiently kneaded with a binder made of a polyurethane resin, an acrylic resin latex, or an equivalent soft resin. The inorganic germanium fine powder is added in an amount of 5 to 10% by weight based on the binder resin solution. The germanium-containing layer 12 is applied on the back sheet 5 by a silk screen method or a roll coater method, and the thickness may be 10 to 40 μm. The resin binder may be any of a resin latex, a resin emulsion, a resin suspension, a hydrophilic copolymer, a chemically reactive water-soluble resin, and the like as long as the fine powder of inorganic germanium can be uniformly kneaded.

  Regarding the germanium-containing layer 12, the resin binder is preferably a polyurethane-based resin. Polyurethane resins are, for example, thermally crosslinkable or crosslinkable over time, and generally have a low density, so that germanium ion permeability is even better than other resins. The polyurethane-based resin has excellent elongation, abrasion resistance, impact resilience, and compression fatigue strength, and hardly causes delamination or cracks when attached to an affected area.

  In order to wrap and fix the health band 1, it is desirable to sew one of the surface fasteners to the front end of the band body 2 and the other of the surface fasteners to the rear end. The hook material 18 of the hook-and-loop fastener is sewn to the rear end of the back side of the band main body. For fixing the health band 1, a known hook or button may be attached instead of or together with the hook-and-loop fastener.

  Regarding the hook and loop fastener, the loop material 16 is provided with a multifilament loop such as nylon or polyester standing on the base fabric, and engages with the hook material 18 to develop a sufficient locking force. Even if the hook material 18 is formed by standing monofilaments such as nylon or polyester in a loop shape on a base fabric and cutting off one side portion of the loop to form a hook shape, the top portion of the loop is cut to a pointed end. May be formed into a mushroom shape by hot melting into a spherical shape. Although not shown, the loop member 16 and the hook member 18 may be a hook / loop mixed type in which both are erected, and both of the mixed type surface fasteners may be sewn to the back side end portion of the band main body 2.

  Since the health band according to the present invention is flexible, it can be expanded and contracted according to the movement of the body when wrapped around the ankle or wrist, etc., so there is little discomfort, and it is possible to sleep, eat, exercise, and other It is possible to work. When the health band of the present invention is wound, the lower resin layer of the back sheet comes into direct contact with the wearer's skin, far infrared rays are diffused from the negative ion generation layer, and at the same time, germanium ions are generated from the germanium-containing layer, It works effectively on the affected area of the wearer.

  If the health band of the present invention is kept worn for a certain period of time, the temperature inside the band rises by the radiation of far infrared rays, and the wearer's entire wearing part is warmed, and the heat effect promotes sweating and generates negative ions. When the health band of the present invention is worn, the subcutaneous layer of the skin at the wrapping site of the wearer is easily ionized by the generated negative ions, and the permeability of germanium ions to the dermis of the skin is increased. Germanium ions generated from the germanium-containing layer tend to penetrate the skin of the foot, instantly harmonize the disturbed bioelectric current in the foot to relieve muscle tension, relieve blood congestion, improve blood circulation and fatigue the foot And relieve pain.

  The health band according to the present invention generates both negative ions and germanium ions simultaneously and effectively, thereby causing many pains such as neck / shoulder stiffness, neuralgia, whiplash, fifty shoulders, low back pain, tight waist, knee pain, foot pain. Therapeutic effects on pain, sprains, sciatica, rheumatoid arthritis, tinnitus, etc. can be expected. This health band can guarantee its safety because high-purity inorganic germanium has been approved by the Ministry of Health, Labor and Welfare. The higher the purity of germanium in this health band, the more effective the treatment. When the purity is 99.999% or higher, the destruction of muscle cells due to active oxygen harmful to the human body can be reliably suppressed, and wrapping can cause pain. No side effects such as rash, redness or inflammation occur during use.

  Next, although this invention is demonstrated based on an Example, this invention is not limited to an Example. 1 and 2 show an example of a health band 1 according to the present invention. The band main body 2 in the health band 1 has, for example, a band shape having a length of 350 mm and a width of 60 mm, and is configured by combining two sheets of a front side sheet 3 and a back side sheet 5 as shown in FIG. The front side sheet 3 and the back side sheet 5 are each composed of a foamed urethane-based upper resin layer 6, a polyester thin cloth reinforcing cloth 7 disposed in the middle, and a foamed urethane-based lower resin layer 8 laminated with the reinforcing cloth. It has a three-layer structure and a thickness of about 1 mm.

  A predetermined amount of aluminum fine powder is added to the urethane resin in the upper resin layer 6 of the front sheet 3 and the whole is silver white. On the surface of the upper resin layer 6, an appropriate surface pattern 9 made of a trademark or a figure is printed. This surface pattern may be printed after printing on each front side sheet 3 or before cutting, and may be a transfer pattern by a transfer sheet or the like.

  On the other hand, the lower resin layer 8 of the back sheet 5 is embossed with fine embossing on the entire surface. As shown in FIG. 3, a green negative ion generation layer 10 containing a fine powder of a negative ion generation material is formed on the entire lower resin layer 8. The negative ion generation layer 10 includes, for example, a ceramic powder that is an alumina-silica ceramic having an average particle size of 1.2 μm as a negative ion generation material.

  The 20 wt% alumina-silica ceramic powder is mixed with 70 to 90 wt% of a polyurethane resin solution having a solid content of 20%. To 100 g of this mixed solution, 2 g of silica gel, 5 g of an organic solvent and a green pigment are added and stirred, and further 5 g of isocyanate is added. The negative ion generation layer 10 is formed entirely on the lower resin layer 8 by a 180 mesh silk screen plate, and is printed twice with the same screen plate to a thickness of about 15 μm.

  Further, as the germanium-containing layer 12, a black pattern portion 14 containing inorganic germanium fine powder is formed on the negative ion generation layer 10. Inorganic germanium having a purity of 99.999% is a fine powder having an average particle diameter of 7 μm, and is sufficiently kneaded with 8% by weight of this fine powder and 92% by weight of polyurethane resin latex. The appropriate design portion 14 is dispersedly formed on the negative ion generation layer 10 by a 200-mesh silk screen plate, and is printed twice with the same screen plate to determine a thickness of about 10 μm. The pattern portion 14 needs to have a partially dispersed pattern so that the negative ion generation layer 10 is more than half exposed.

  The band main body 2 has a loop material 16 of a hook-and-loop fastener sewn on the front end portion of the front side sheet 3, and the length of the loop material is 90 mm. A hook material 18 of a hook-and-loop fastener is sewn to the rear end portion of the back sheet 5, and the length of the loop material is 50 mm. After these sewing operations, the front side sheet 3 and the back side sheet 5 are superposed to hide the stitches of the sewing machine, and a black edge cloth 19 is stitched on the entire circumference of the band body 2.

  As illustrated in FIG. 4, when the health band 1 is wrapped around the ankle 21 of the wearer 20 and fixed, the lower resin layer 8 of the back sheet 5 comes close to the skin of the wearer 20, and the negative ion generation layer 10 and germanium. When the containing layer 12 is in direct contact, far-infrared rays are diffused from the negative ion generating layer 10 and germanium ions are generated from the germanium containing layer 12 to act on the affected part of the wearer 20. If the health band 1 is kept worn for a certain period of time, the far-infrared rays are reflected by the upper resin layer 6 to which aluminum powder is added, the far-infrared rays hit the entire ankle of the wearer 20, and the inside of the band is irradiated by far-infrared radiation. It rises and promotes sweating by its thermal effect, generating negative ions.

  In the health band 1, when negative ions are generated, the subcutaneous layer of the skin at the ankle 21 of the wearer 20 is easily ionized, and the permeability of germanium ions to the dermis of the skin is increased. Germanium ions generated from the germanium-containing layer 12 easily penetrate the skin of the foot, instantly harmonize the disturbed bioelectric current in the foot to relieve muscle tension, release blood congestion, improve blood circulation, Relieve fatigue and pain. Germanium ions are highly effective in relieving fatigue without causing side effects such as rash, redness, and inflammation during use.

  FIG. 5 shows a modification of the present invention. The band main body 23 of the health band 22 is a belt having a length of 240 mm and a width of 30 mm, and for women, the band is 215 mm. The band main body 23 is composed of two sheets of a front side sheet 24 and a back side sheet 26 as described above, and the layer structure and material of both sheets are the same as described above.

  The bottom resin layer of the back sheet 26 is formed with fine embosses embossed on the entire surface by embossing, and then, as shown in FIG. 6, yellow-green negative ions containing fine powders of negative ion generating substances. The generation layer 28 is laminated. For example, EM ceramic powder is added to the negative ion generation layer 28 as a far-infrared emitting material. 30% by weight of EM ceramic powder is mixed with 70 to 90% by weight of a polyurethane resin solution having a solid content of 20%. To 100 g of this mixed solution, 2 g of silica gel, 5 g of an organic solvent and a yellow-green pigment are added and stirred, and further 5 g of isocyanate is added. The negative ion generation layer 28 is dispersedly formed in a lattice pattern by a 180-mesh screen plate, and is printed twice with the same screen plate to a thickness of about 11 μm.

  Further, as described above, inorganic germanium having a purity of 99.999% was used as the germanium-containing layer 30, and the germanium was a fine powder having an average particle diameter of 7 μm. The fine powder was 8% by weight and the polyurethane resin latex was 92% by weight. And kneaded thoroughly. The germanium-containing layer 30 is densely formed in a lattice shape between the negative ion generation layers 28 on the lower resin layer by a 200-mesh silk screen plate, and is printed twice with the same screen plate to have a thickness of about Set to 10 μm.

  The band main body 23 has a loop material 32 of a hook-and-loop fastener sewn to the front end portion of the front side sheet 24, and the length of the loop material is 42 mm. A hook material 34 of a hook-and-loop fastener is sewn to the rear end portion of the back side sheet 26, and the length of the loop material is 20 mm. After these sewing operations, the front side sheet 24 and the back side sheet 26 are superposed to hide the stitches of the sewing machine, and a black edge cloth 36 is stitched on the entire circumference of the band main body 23.

  As shown in FIG. 7, the health band 22 is wound around the wrist 38 of the wearer 36 and fixed. The lower resin layer of the back sheet 26 is close to the skin of the wearer 36, far infrared rays are diffused from the negative ion generation layer 28, and germanium ions are generated from the germanium-containing layer 30. If the health band 22 is kept worn for a certain period of time, far infrared rays hit the entire hand of the wearer 36, the temperature inside the band rises by the radiation of far infrared rays, and the heat effect promotes sweating and generates negative ions.

  FIG. 8 shows another modification of the present invention. In the health band 40, elongated rectangular insertion pieces 44, 46 are arranged orthogonally on the front side front portion and the rear side portion of the band main body 42. The insertion pieces 44 and 46 may be a transparent or translucent plastic sheet. The insertion pieces 44, 46 are sewn together at the front and back when the edge cloth 48 is sewn around the band main body 42, so that when the sheet piece such as the health management table 50 is inserted, the health band 50 is inserted. 40 can be locked.

  The health band 40 is wound around the wrist during jogging or marathon (see FIG. 7), and the wearer's health management table 50 is passed through both the insertion pieces 44 and 46 and fixed. Since the health management table 50 describes the blood type and past symptoms of the wearer, a quick first aid can be taken from the health management table 50 when an accident occurs.

It is a top view which illustrates the health band concerning the present invention. It is a rear view which shows the back surface of the health band of FIG. It is a fragmentary sectional view which expands and shows the health band of FIG. It is a schematic side view of a wearer's ankle which shows the usage example of the health band of FIG. It is a top view which shows the health band which is a modification of this invention. It is a rear view which shows the back surface of the health band of FIG. It is a schematic side view of a wearer's wrist which shows the usage example of the health band of FIG. It is a top view which shows the front side of the health band which is another modification.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Health band 2 Band main body 3 Front side sheet 5 Back side sheet 10 Germanium containing layer 12 Negative ion generation layer 16 Loop material of a surface fastener 18 Hook material of a surface fastener

Claims (5)

  On the lower surface of the band body made of a soft flexible resin, a negative ion generation layer in which a fine powder of a negative ion or far-infrared generation substance is mixed with a resin binder and a fine powder of high purity inorganic germanium are resin When formed by mixing a germanium-containing layer mixed with a binder and wrapped around the wrist, ankle, waist, or head of the wearer, the negative ion generation layer and the germanium-containing layer are in direct contact with the skin. A healthy band that acts on the wearer.   The band body is composed of two soft resin sheets with reinforcing cloth interposed between them. The front side sheet contains fine metal powders such as aluminum and silver added to the resin, and negative ions on the lower surface of the back side sheet. Alternatively, it is formed by mixing a negative ion generation layer coated with a fine powder of a far-infrared generator mixed with a resin binder and a germanium-containing layer coated with a high-purity inorganic germanium fine powder mixed with a resin binder. A health band in which the negative ion generation layer and the germanium-containing layer are in direct contact with the skin and act on the wearer when wrapped around the wrist, ankle, waist, and head of the wearer and fixed.   The band body consists of two urethane resin sheets with a reinforcing cloth interposed between them. One of the surface fasteners is sewn to the front end of the band body, and the other of the surface fasteners is sewn to the rear end. A negative ion generation layer in which a fine powder of a negative ion or far-infrared generating substance is mixed with a polyurethane resin on the lower surface of the band main body, and a high purity inorganic germanium fine powder and a polyurethane resin. Formed by mixing mixed germanium-containing layers, wrapped around the wearer's wrist, ankle, waist, head, etc. and fixed with hook-and-loop fasteners, feels good, negative ion generation layer and germanium-containing layer A healthy band that acts directly on the wearer when in contact with the skin.   The health band according to claim 1, 2 or 3, wherein a predetermined amount of the coating amount of the negative ion generation layer and the germanium-containing layer is maintained by embossing a fine grain on the lower surface of the back sheet. As a health band for jogging and marathon, when sewing a hemcloth around the band body, by sewing the front and back of the band body at the same time before and after the insertion piece, The health band according to claim 1, 2 or 3, which can be fixed through both insertion pieces.

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